Piezoelectric ceramic composition



May 26, 1970 TSUNEO AKASHI ETAL PIEZOELECTRIC CERAMIC COMPOSITION Original Filed Oct. 17, 1966 5 Sheets-Sheet 1 INVENTORS HH I Isc N ma m M40 r ne r KAu 4 Ars 00T Av M1 M May 26, 1970 rsuNl-:o AKAsHl Erm. 3,514,404

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May 26, 1970 rsuNEo AKAsHl ETAL 3,514,404

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May 26, 1970 TsuNEo AKAsHl ETAL 3,514,404

PIEZOELECTRIC CERAMIC COMPOSITION Original Filed Oct. 17, 1966 5 Sheets-Sheet 5 Mam/M5403 FIG-.6

United States Patent O 3,514,404 PIEZOELECTRIC CERAMIC COMPOSITION Tsuneo Akashi, Masao Takahashi, and Norio Tsubouchi, Tokyo, Japan, assignors to Nippon Electric Company, Limited, Tokyo, Japan, a corporation of Japan Original application Oct. 17, 1966, Ser. No. 587,241. Divided and this application Apr. 15, 1969, Ser. No. 817,273 Claims priority, application Japan, Oct. 19, 1965, 40/64,094; Dec. 15, 1965, 40/76,660, t0/76,661 Int. Cl. H04b 35/00 U.S. Cl. 252-623 3 Claims ABSTRACT OF THE DISCLOSURE A piezoelectric ceramic composition of the formula (PbuAv) (ZrxTiySnz)O3, where A represents at least one member selected from a group consisting of calcium, strontium, and barium and u, v, x, y, and z are given by u=0.751.00, v=0.000.25, u-l-v=1.00, x=0.000.90, y=0.100.60, z=0.000.65, and x|-y+z=1.00, characterized in that said ceramic composition contains a set of additional constituents consisting of a nickel compound equivalent in amount to nickel oxide of from 0.02 to 2.0 Weight percent and a chromium compound equivalent in amount to a chromium sesquioxide of from 0.01 to 0.50 weight percent, each of said weight percentages being the percentage of the total weight of said ceramic composition.

This is a division of application Ser. No. 587,241 tiled Oct. 17, 1966, now U.S. Pat. No. 3,481,874.

This invention relates generally to piezoelectric ceramic compositions. More particularly, this invention relates to ceramic compositions based on a formula of lead zirconate-lead titanate PbZrO3-PbTiO3 or on a related formula lead zirconate-lead titanate-lead stannate PbZrO3- PbTiO3-PbSnO3.

The present invention relates more particularly to lead zirconate-lead titanate-lead stannate (PbZrO3-PbTiO3- PbSnO3) -ceramic compositions which contain, in addition to such compositions, chromium sesquioxide (Cr203) of from 0.01 weight percent to 0.7 weight percent of the total weight and also gallium sesquioxide (Ga203) of from 0.01 weight percent to 1.5 weight percent.

The present invention also relates to PbZrO3-PbTiO3- PbSnO3 ceramic compositions which contain, in addition to such compositions, manganous oxide (MnO) of from 0.02 weight percent to 1.0 weight percent of the vtotal weight and also nickel oxide (NiO) of from 0.02 weight percent to 2.0 weight percent.

The present invention further relates to PbZrO3PtTiO3 PbSnO3 ceramic compositions which contain, in addition to such compositions, nickel oxide (NiO) of from 0.02 to 2.0 weight percent and valso chromium sesquioxide (C1203) of from 0.01 to 0.5 weight pencent.

A general object of this invention is to provide ceramic compositions having large electromechanical coupling factors and large mechanical quality factors.

A further object of this invention is to provide piezoelectric material which have both large electromechanical coupling factors and large mechanical quality factors for use as elements of ceramic electric wave filters and as transducer elements of mechanical filters.

It can be established that a lead zirconate-lead titanate solid solution Pb(ZrTi)O3, obtained by sintering a mixture of lead zirconate PbZrO3 and lead titanate PbTiO3, has piezoelectric properties which are stable against change of temperature and elapse of time and that strong piezoelectric actlvlties are achleved 1n the nelghborhood ICC Fundamental measures for evaluating the piezoelectric properties of a piezoelectric material are its electromechanical coupling factor and its mechanical quality factor. The electromechanical coupling factor represents the efficiency of transforming electric oscillation into mechanical vibration and, conversely, of transforming mechanical vibration into electric oscillation. The mechanical quality factor represents the reciprocal proportion of the energy consumed by the material during the electrical and mechanical energy interconversion. A larger mechanical quality factor corresponds to a smaller energy consumption by the material, and vice versa.

Recently, attention and studies have been directed to ceramic electric wave filters wherein use is made of piezoelectric ceramics as the element or elements of the filters, and to mechanical filters wherein use is also made of piezoelectric ceramics as the transducer or transducers thereof. The qualities desired for the piezoelectric ceramics used in these fields of application are as follows: For the elements of ceramic electric wave filters, the electromechanical coupling factor must have a desired value selected from a range between an extremely large value and a very small value, and the mechanical quality factor should have as great a Value as possible. For the transducer elements of mechanical filters, both the electromechanical coupling factor and the mechanical quality factor must be as large as possible. Thus, the properties required for the transducer elements of mechanical filters are consistent with that particular set of properties demanded for the elements of ceramic electric wave filters in which the electromechanical coupling factor is large.

The electromechanical coupling factor determines the frequency spacing between the attenuation poles of the filter in such a manner that a greater electromechanical coupling factor produces a filter of wider frequency spacing and a smaller electromechanical coupling factor results in a filter of narrower frequency spacing. In other words, the electromechanical coupling factor of the piezoelectric material for the elements of ceramic filter must be selected in compliance with the frequency spacing between the attenuation poles of the particular filter in which the material is to be used and that factor must therefore be available or adjustable between an extremely small value and a very large value according to the characteristics of the filter. The mechanical quality factor also determines the loss in the pass band and the loss at the attenuation poles of the filter. The values desired for a filter therefore determine the lowest allowable limit of the mechanical quality factor of the piezoelectric material to be used in the filter. In other words, a piezoelectric material having a smaller mechanical quality factor than required can not provide a satisfactory filter, while a piezoelectric material having a greater mechanical quality factor than required can easily provide a filter of excellent chanacteristics. A greater mechanical quality factor is generally necessary for piezoelectric materials to -be used in a filter of narrower pass band or for a case where a smaller electromechanical coupling factor is required.

As has so far been described, piezoelectric material for use in filters must be furnished with the electromechanical coupling factor selected from a wide range according to the characteristics and the fields of application of the particular filter and with the largest possible mechanical quality factor.

According to this invention, the basic composition of lead zirconate-lead titanate may incorporate any one of the respective pairs of additives above noted, that is,

o Ga203 and Cr203, NiO and MnO, and NiO and Cr203, in

strontium (Sr) and calcium (Ca) may replace up to 25 atom percent of the lead (Pb) contained in the basic composition.

It is especially noted, as will be explained by Way of example, that improvements in the characteristics of the various compositions of this invention may be brought about by the addition of gallium oxide, chromium sesquioxide, nickel oxide, and manganous oxide, in the amounts and in the combinations specied herein, and such improvements clearly result from the presence of gallium ions, chromium ions, nickel ions and manganous or manganese ions, respectively, in the lead zirconate-lead titanate ceramics. Gallium compounds [for example, GaClg or Ga2(SO4)3], other than gallium sesquioxide (GazOa), may be used in the composition so as to provide an amount of gallium ions equivalent to that derived from gallium sesquioxide (GaZOa). Similarly chromium compounds (for example CrCls), other than chromium sesquioxide (Cr203), may be used in the composition so as to provide an amount of chromium ions equal to the amount of chromium ions provided lby chromium sesquioxide (Cr203) when it is used in the composition. Also, if nickel compounds, other than NiO, are employed, they should be supplied in amounts to yield nickel ions in an lamount equivalent to that of NiO. Furthermore, if manganous or manganese compounds, other than MnO, are utilized, they should be used in amounts equivalent to the desired Weight of MnO for yielding the appropriate amount of manganous or manganese ion.

This invention may also be expressed as residing in a piezoelectric ceramic composition Whose basic composition may be represented by Pb (ZrXTiySnZ)O3, Where x, y, and z represent a set of mol ratios and such mol ratios are given by Compositions outside of the suggested ranges are not practically operable because of their seriously reduced electromechanical coupling factors. The largest electromechanical coupling factor is obtainable in cases in which x, y, and z are in the vicinities of 0.52-0.53, OAS-0.47, and 0.00, respectively. Also, excellent piezoelectric properties are obtained even if at least one member of the group of calcium, strontium and barium may be substituted for up to 25 atom percent of the lead contained in the basic composition.

Details of certain earlier types of replacements or substitutions in piezoelectric materials are generally described, for example, in Journal of the National Bureau of Standards, 55 (1955), 239 by B. Jaffe, R. S. Roth, and S. Marzullo and in U.S. Pats. No. 2,906,710 issued to F. Kulcsar et al. on Sept. 29, 1959, and No. 3,068,177 issued to J. A. Sugden on Dec. 1l, 1962.

Said basic composition may contain, as additional constituents, both gallium sesquioxide (Ga203) of from 0.01 Weight percent to 1.5 Weight percent of the total Weight and chromium sesquioxide (Cr2O3) of from 0.01 Weight percent to 0.70 Weight percent of the total Weight.

The compositions of this invention may also consist ofthe above-noted basic composition of Pb (ZrXTiySnz)O3 where x, y, and z are given by the above equations and where at least one member of the group of calcium, strontium and barium may be replaced by up to 25 atom percent of lead (Pb) contained in the basic composition, and such basic composition may include additional constituents of nickel oxide (NiO) of from 0.02 weight percent to 2.0 weight percent and also manganese oxide (MnO) of from 0.02 weight percent to 1.0 Weight percent.

The compositions of this invention may also consist of the above-noted basic composition of Pb(ZrXTiySnZ)O3,

where x, y, and z are given by the above equations and Where at least one member of the group of calcium, strontium and barium may be replaced by up to 25 atom percent of the lead (Pb) contained in said basic cornposition, and to said basic composition there may be added constituents of nickel oxide (NiO) of from 0.02 Weight percent to 2.0 Weight percent and also chromium sesquioxide (01'203) of from 0.01 weight percent to 0.5 weight percent.

The resulting basic compositions above-noted are especially suitable as piezoelectric materials for the elements of electric Wave filters and for the transducer elements of mechanical lilters.

As for the piezoelectric materials to be used in the elements of ceramic electric wave filters, it is necessary that such materials provide an electromechanical coupling factor With an optimum values elected from a wide range eX- tending from an extremely large value to a very small value, and it is also desirable for the mechanical quality factor to have as great a value as possible. This criterion is described, for example, in Electronic Engineering, Vol. 33 (1961), No. 3, pp. 171-177, by R. C. V. Macario, entitled Design Data for Band-Pass Ladder Filters Employing Ceramic Resonators.

This invention will be better understood from the more detailed description hereinafter following when read in connection with the accompanying drawing in which:

FIG. l shows curves representing the electromechanical coupling factor Kr for the radial mode vibration and the mechanical quality factor Qm, both plotted as ordinates, against abscissae representing the content of chromium sesquioxide (Cr203) in ceramics obtained by adding, to the composition Pb(Zr0h52Ti0 48)O3, the compound gallium sesquioxide (Ga2O3) of 0.50 Weight percent and the compound chromium sesquioxide (Cr203) of up to 0.70 Weight percent. These curves are based upon compositions given, for example, in Table 1 listed hereinafter.

FIG. 2 shows curves representing the factors Kr and Qm, both plotted as ordinates, against abscissae representing the content of gallium sesquioxide (Ga203) in ceramics obtained by adding, to the composition Pb(Zr0,52Ti0.48)O3, the compound chromium sesquioxide (Cr2O3) of 0.10 weight percent and the compound gallium sesquioxide (Ga2O3) of up to 1.5 weight percent. The curves of FIG. 2 are based on compositions given, for example, in Table 2 listed hereinafter.

FIGS. 3 and 4 show similar curves representing the electromechanical coupling factor Kr for the radial mode vibration and the mechanical quality factor Qm, both plotted as ordinates, for the composition to which NiO and MnO compounds have been added. In FIG. 3, the abscissae are MnO and in FIG. 4 they are NiO. The curves of FIG. 3 are based on compositions given in Table 5; the curves of FIG. 4 are based on Table 6.

FIGS. 5 and 6 show similar curves for the same Kr and Qm factors. The abscissae of FIG. 5 are related to the addition of the compound chromium sesquioxide (Cr203), While the abscissae of FIG. 6 are related to the addition of the compound nickel oxide (NiO). The curves of FIG. 5 are based on the compositions given in Table 10; the curves of FIG. 6 are 'based on the compositions of Table l1.

Reference is now made to FIG. 1 showing curves representing, as already noted, the electromechanical coupling factor Kr for the radial mode vibration and the mechanical quality factor Qm, both plotted as ordinates as shown, against abscissae representing the content of chromium sesquioxide (Cr2O3) in ceramics Whose basic composition is given by the term Pb(Zr0.52Ti0 48)O3 and Whose additional constituents are gallium sesquioxide (Ga2O3) of 0.50 weight percent of the total weight and chromium sesquioxide (CrgOa) of up to 0.70 Weight per= cent of the total weight. This composition and the additives which are considered in Table 1, provide the basis l for the curves of FIG. 1.

The lead zirconate-lead titanate composition given by the term Pb (Zr0.52Ti0,48)03, if piezoelectrically activated through polarization treatment effected at 100 C. has a set of values of about 42 percent for the factor Kr and about 250 for the factor Qm. FIG. l and Table 1 show that the addition of 0.50 weight percent of gallium sesquioxide (Ga203) alone to the composition augments the factor Qm to a remarkable extent. The curves and Table 1 furthermore show that the addition of both gallium sesquioxide (GazOs) of 0.50 weight percent and chromium sesquioxide (Cr203) of from 0.01 weight percent to 0.70 Weight percent remarkably augments the value of the factor Kr while not deteriorating or even further augmenting the value of the factor Qm resulting from the addition of gallium sesquioxide (Ga203) alone. This combination provides excellent piezoelectric materials for use in ceramic electric lilters where a large Kr factor is required and for use in transducers f mechanical iilters. The curves still further show that the piezoelectric Vactivities are little improved by coexistence of chromium sesquioxide (Cr203) and gallium sesquioxide (Ga203) in case the content of chromium sesquioxide (Cr203) is less than 0.01 weight percent. Although not shown by the curves, the results of experiments also show that chromium sesquioxide (Cr-203), if contained in excess of 0.70 Weight percent, reduces the electric resistivity of the composition so as to disable thorough polarization treatment and this results in a decrease in both of the Kr and Qm factors and a consequent marked deterioration of the piezoelectric properties.

In view of the above results, the effective range for the content of chromium sesquioxide (Cr2O3) in the case in which both gallium sesquioxide (Ga203) and chromium sesquioxide (Cr203) are added to the composition, is set at between 0.01 weight percent and 0.70 weight percent.

Reference is now made to FIG. 2 which shows curves which represent, as already noted, the relations between factors Kr and Qm, on the one hand, and the content of gallium sesquioxide (Ga203), on the other hand, in the ceramics whose basic composition is lead zirconatelead titanate given by the formula Bb(Zr0,52Ti0.43)03 as Was the case with FIG. 1 and whose additional constituents are gallium sesquioxide (Ga203) of up to 1.5 weight percent and chromium sesquioxide (Cr203) of 0.10 weight percent. The combination of such constituents are included in Table 2.

FIG. 2 and Table 2 show that the addition of 0.10 weight percent of chromium sesquioxide (Cn-03) alone of from 0.01 Weight percent to 1.5 weight percent not only further augments, or, at the worst, only slightly deteriorates, the value of the factor Qm resulting from the addition of chromium sesquioxide (Cr203) but also remarkably raises the value of the factor Kr to provide materials having excellent piezoelectric properties. The curves still further show that the piezoelectric properties are little improved even by coexistence of the compounds gallium sesquioxide (Ga203) and chromium sesquioxide (Cr203) in case the content of gallium sesquioxide (Ga203) is less than 0.01 weight percent. Although not shown by the curves, the results of experiments sho-w that improvements in the properties are scarcely expected from the addition of both gallium sesquioxide (Ga203) and chromium sesquioxide (Cr203) if the content of gallium sesquioxide (GaZOa) exceeds 1.5 weight percent. In other words, in case the content of gallium sesquioxide (Ga203) is more than 1.5 weight percent, Iboth Kr and Qm factors decrease with any increase in the content of gallium sesquioxied (GazOg) and the piezoelectric properties achieved are poorer than those attained by the addition of chromium sesquioxide (Cr203) a one.

From the foregoing, a range between 0.01 Weight percent and 1.5 weight percent is selected for the content of gallium sesquioxide (GazOg) in the case of coexistence of galliumk sesquioxide (Ga203) and chromium sesquioxide (Cr203).

Some examples of this invention will be given hereunder.

Example 1.-1Results shown in Table l So that the resulting basic composition may be given by Pb(Zr0 52Ti0 48)O3, 50 mol percent of lead monoxide (PbO), 26 mol percent of zirconium dioxide (ZrOz), and 24 mol percent of titanium dioxide (TiOZ) were arranged for various mixtures, such constituents were supplied with an additive of 0.50 weight percent of gallium sesquioxide (Ga203), and these constituents were supplied with further additives of from 0.01 weight percent up to 0.70 Weight percent of chromium sesquioxide (Cr203). As shown in Table l, these compounds were then mixed, respectively, in a ball mill, pre-sintered |at 900 C. for an hour, crushed, press-moulded into discs, sintered at 1300 C. for an hour, provided with silver electrodes, respectively, subjected to a polarization treatment at 100 C. for an hour under an electric field of 50 kv./cm., allowed to stand for 24 hours, and then the factors of Kr and Qm were measured. The results obtained for the various combinations are shown in Table 1. The results were obtained for the rbasic composition alone (No. 1) and for the basic composition with an addition of 0.50 weight percent of gallium sesquioxide (Ga203) alone (No. 2).

l CrCla was contained in au amount equivalent to 0.20 wt. percent of CriOa.

Comparison of the results Nos. 1 and 2 of Table 1 shows that the addition of Ga203 of 0.50 weight percent (No. 2) to the basic composition (No. 1) raises the factor Qm to a large extent. rIhe results Nos. 3-9 show that the addition of chromium sesquioxide (CrzOa) in of 0.10 weight percent and gallium sesquioxide (Ga203) amounts extending from 0.01 weight percent to 0.70

weight percent, with the content of gallium sesquioxide (Ga2O3) kept at 0.50 Weight percent, remarkably raises the value of the factor Kr while not deteriorating the value of Qm for lany arrangement including gallium sesquioxide (GagOg).

In the following examples, the results were achieved through treatments similar to those given in the prior example (unless otherwise mentioned).

Example 2,-Results shown in Table 2 Table 2 shows the results obtained for a mixture of the composition Pb(Zr 52Ti0 48)O3 and 0.10 weight percent of the compound chromium sesquioxide (Cr2O3) alone, and for mixtures of this same compound Cr2O3 and compounds of from 0.01 weight percent to 1.5 weight percent of the compound gallium sesquioxide ((351203)- These results clearly show that, regardless of change of the contents of Zr and Ti in the basic composition in the manner exemplied in this Table 3, the piezoelectric properties are remarkably improved by the addition thereto of both gallium sesquioxide (Ga2O3) of 0.50 weight percent and chromium sesquioxide (Cr2O3) of 0.10 weight percent. If compared with the result No. 6 of the example shown in Table 1, the results of Table 3 prove that excellent piezoelectric materials are obtained by the addition of both gallium sesquioxide (Ga203) and chromium sesquioxide (Cr203) to whichever of the basic compositions of these compositional formulae are employed.

Example 4.-Results shown in Table 4 Table 4 shows the Kr and Qm factors obtained when both a compound of 0.50 weight percent of gallium TABLE 2 Composition percent Qm Pb (Zr ,52Ti0 45)03 plus 0.10 wt. percent CrzOs 51 770 11- Pb (Zr0,5g'1i0 4s)03 plus 0.01 wt. percent Ga203 plus 0.10 wt. percent CrzO; 54 780 12 Pb(Zr0.52Ti0.4g)O3 plus 0.02 Wt. percent GazO; plus 0.10 Wt. percent CrnOa 59 820 13.-- Pb(Zru,52Ti0 4g)O3 plus 0.05 Wr. percent GaaOa plus 0.10 Wt. percent CrgOa 60 830 M Pb(Zr0 52Ti0 4g)O3 plus 0,10 wt. percent GagOa plus 0.10 Wt. percent CrzOa 60 830 15. Pb(Zru,5zTiu.4)O3 plus 0.20 wt. percent GazOa 1 plus 0110 wt. percent CrgOa. 60 820 16. Pb(Zru,5Tiu.45)O3 plus 1.1 Wt. parcett GazOa plus 0.10 wt. percent CMO; 57 730 17 Pb (Zro,szTi0.4s)Oa plus 1.5 Wt. percent GazOa plus 0.10 Wt. percent CrgOg 52 700 1 GaCl; was contained in an amount equivalent to 0.20 Wt. percent of GazOa.

Comparison of the result No. 1 of Table 1 with the 30 sesquioxide (Ga2O3) and a compound of 0.10 weight result No. 10 of Table 2 shows that addition of 0.10 Weight percent of Cr203 alone to the 'basic composition is suicient to signiiicantly augment both the Kr and Qm factors. The results Nos. 11 through 17 show that the addition of gallium sesquioxide (Ga2O3) of `from 0.01 weight percent to 1.5 weight percent with the content of percent of chromium sesquioxide (Cr2O3) are contained in each of lead titanate-lead zirconates, wherein the Zr:Ti ratio is 52:48, and wherein barium (Ba) and strontium (Sr) are substituted for 5.0 atom percent of the lead1 forming a portion of the basic compositions, respective y.

chromium sesquioxide (CrzOa), kept in all these cases Nos. 11 to 17 at 0.10 weight percent, remarkably raises the value of the factor Kr while further augmenting or, at the worst, only slightly reducing, the value of the factor Qm when compared with the results of the addition of chromium sesquioxide (Cr2O3) (see Table l). These results show that these compounds yield excellent piezoelectric materials for use in cases where a large Kr factor is specically required.

Example 3.-Results shown in Table 3 Table 3 shows the Kr and Qm factors obtained from lead `zirconate-lead titanate compositions wherein 0.45, 0.50, and 0.55 were selected for x in the compositional formula Pb(ZrxTi1 x)O3 and from compositions obtained -by having both the 0.50 Weight percent of gallium sesquioxide (Ga203) and the 0.10 weight percent of Example 5.-Results shown in Table 5 So that the resulting basic composition may be represented by the formula Pb (ZrOjZTiMQOa, the composition included powder consisting of 50 m01 percent of lead monoxide (PbO), 26 mol percent of zirconium dioxide chromium sesquioxide (Cr203) contained in each of the (ZrOg), and 24 H101 Percent 0f titanium dioxide (Tioz), basic compositions. and to this composition were added both a 0.20 weight TABLE 3 Kr, Composition percent Qm Number:

18 Pb(Z1'o.45Tio,5s)0a 11 320 19 Pb(Zr0 45Ti0\-,5)Og plus 0.50 Wt. percent Gago; plus 0.10 wt. percent CrrOa- 33 940 20..- Pb(Z1`o.soTio.so)O 29 340 21 Pb(Zl`u 5oT1o 50)()3 plllS 0 43 810 Pb(Zl0.55Tlo.45)Oa 39 320 Pb (Z1'0 55T10.45) O3 plus 0.50 wt. percent GaqOg plus 0,10 wt. percent Cri 58 770 percent of nickel oxide (NiO), and a compound of manganous oxide (MnO), in the stated amounts specified in Table 5, but in two of the cases (Nos. 7 and 9) a compound of manganese carbonate (MnCo3) in the amounts noted in Table was used as an additional constituent (the MnCo3 being computed as if MnO were added). These chemicals were mixed in a ball mill. Mixed powder of the respective kinds was pre-sintered at 900 C. for an hour, crushed, press-moulded into discs, and sintered at 1300 C. for an hour. The resulting ceramic discs were provided with silver electrodes and piezoelectn'cally activated through polarization treatment at 100 C. for an hour under an electric field of 50 kv./ cm. After the discs had been allowed to stand for 24 hours, the electromechanical coupling factor Kr for the radial mode vibration and the mechanical quality factor Qm were measured to evaluate the relative piezoelectric activities. Typical results are shown in Table 5.

provide excellent material for use in the piezoelectric components of ceramic wave filters Where specifically large Kr factors are required and in transducers of mechanical filters.

In case the content of manganous oxide (MnO) is less than 0.02 weight percent, coexistence of' the compounds nickel oxide (NiO) and manganous oxide (MnO) hardly improves the piezoelectric activities achieved by the presence of nickel oxide (NiO) alone. In case the content of manganous oxide (MnO) exceeds the 1.0 weight percent limit, the properties are so much and so rigidly altered regardless of presence of nickel oxide (NiO) that the coexistence of nickel oxide (NiO) scarely improves the activities.

In view of the above, a range between 0.02 weight percent and 1.0 weight percent has been selected for the effective range of the manganous oxide (MnO) content.

TABLE 5 K1, Composition percent Qm Number 1 Pb (Zl'o.szTu .45) 0s 42 250 2 Pb(Zro.szTio.4s)Oa plus 0.20 wt. percent NiO 55 270 3 Pb(Zrn.azTiu.4a)Oa plus 0.20 Wt. percent NiO plus 0.02 wt. percent Mn0 59 270 4-- Pb(Zr0 tzTioxg) 05 plus 0.20 Wt. percent N10 plus 0.05 wt. percent Mn0 66 270 5.- Pb(Zru.5qTi0.4a)03 plus 0.20 Wt. percent N10 plus 0.10 wt. percent Mn0 66 330 6 Pb(Zrn,52T1t.4g)Oa plus 0.20 wt. percent N10 plus 0.20 wt. percent MnO. 65 940 7 Pb(Zrn T n)Oa plus 0.20 wt. percent N10 plus 0.30 wt. percent MnO 1 63 980 8-- Pb (Zr0.5zTi0,4)Oa plus 0.20 wt. percent N10 plus 0.50 Wt. percent Mn0 60 840 9 Pb (Zro .uTiomOa plus 0.20 wt. percent N10 plus 0.70 wt. percent MnO 1-.- 58 630 Pb(Zr0.5gTlq,4s)0a plus 0.20 wt. percent N10 plus 1.0 Wt. percent Mn0.- 56 880 1 MnOa ls added as calculated on the basis of MnO.

Example 6.-Results shown in Table 6 Table 6 shows the results obtained for a mixture of the basic composition of Pb(Zr(, 52Ti0,43)O3 that is the same as in Example 5 supra and an additional constituent of 0.20 weight percent of manganous oxide (MnO) alone (case No. l1) and for mixtures with further additions of nickel oxide (NiO) of from 0.02 weight percent to 2.0 weight percent as indicated in Table 6 for cases Nos. 12 to 17.

TABLE 6 Kr, Composition percent Qm ber:

Nmill pmzrw'rim) O3 plus 0.20 wt. percent M110 64 350 12- Pb (Zr,52Ti0 4g) 03 plus plus 0.02 wt. percent N10 plus 0.20 Wt. percent 64 400 13- Pb(Zr052Ti 4g) O3 plus p.05 wt. percent N 1O plus 0.20 percent 65 580 14 Pb(Zro.szTio.4a)03 plus 0.10 wt. percent N1 O plus 0.20 wt. percent- 65 820 15 Pb(Zrn.5zTio.4s) 0a plus 0.50 wt` percent N10 l plus 0.20 wt. percent MnO.. 67 720 16 Pb(Zr 52Ti0 4g) O3 plus 1.0 wt. percent N1 O plus 0.20 wt. percent MnO 66 550 Pb (Zr0-52'1i0-48) O3 plus 2.0 wt. percent N10 plus 0.20 wt. percent MnO 65 380 1 NiC03.2Ni(0H) 2.412120 may be added as calculated on the basis of nickel oxide (NiO).

FIG. 3 illustrates curves representing the results of this Example 5. More particularly, the curves show the relations obtained between the Kr and Qm factors on the one hand and, on the other hand, the content of manganous oxide (MnO) in the case of the composition Pb (Zr 52Ti0 48)O3 containing nickel oxide (NiO) of 0.20 weight percent and also manganous oxide (MnO) of 1.0 weight percent or less (in the amounts noted, for instance, in Table 5 As will be clear from Table 5 and FIG. 3, it is possible to raise the Kr factor and remarkably to augment the Qm factor by addition of both nickel oxide (NiO) and manganous oxide (MnO) to the basic composition.

In general, an increase of one of the factors Kr and Qm reduces the other factor. On the contrary, however, the addition of both nickel oxide (NiO) and manganous oxide (MnO) to the basic composition Amakes, it possible to simultaneously raise -both factors Kr and Qm remarkably and to obtain piezoelectric materials having both factors Kr and Qm significantly increased. This serves to Comparison of the result of Case No. 1 of Example 5 shown in Table 5 with the result of Case No. 1l of Table l6 shows that addition of 0.20 weight percent of manganous oxide (MnO) alone to the basic composition provides a piezoelectric material having fairly augmented Kr and Qmf factors. It should be understood, however, that further increases in factor Kr and further increases in factor Qm, which are already augmented by addition of manganous oxide (MnO) alone, would provide piezoelectric materials having a wider field of application because they are improved piezoelectric materials.

vReferring to FIG. 4, curves are shown to represent the results of this Example 6. More particularly, these curves show the relation between factors Kr and Qm on the one hand and, on the other hand, the content of nickel oxide (NiO) in cases in which both nickel oxide (NiO) of 2.0 weight percent or less and manganous oxide (MnO) of 0.20 weight precent (unchanged in amount) are added to the basic composition Pb(Zr0.52Tio 4a)O3, as is exemplified in Table 6'.

1 1 1 2 As is clearly shown in Table 6 and FIG. 4, it is possible Table 7 clearly shows that the indicated changes, in the to provide piezoelectric materials having remarkably above-noted values of x and y in the ceramic composiraised Kr and Qm factors by addition of both nickel Oxide tion (which obviously does not include tin (Sn)) and are (NiO) and manganous oxide (MnO). given by Pb (ZrXTiy)O3, do not deteriorate the piezoelec- In case the content of nickel oxide (NiO) is less than tric properties. The employment of nickel oxide (NiO) 0.02 weight percent, coexistence of nickel oxide (N10) 5 and manganous oxide (MnO) in the modified composiand manganous oxide (MnO) contributes but little t0 the tion serve to maintain the Kr and Qm factors relatively improvement of the piezoelectric properties attalned by high invalues, presence of manganous oxide (MnO) 211011@- In CaSe the Recapitulating, the compositions improved through addition of both nickel oxide (NiO) and manganous content of nickel oxide (NiO) exceeds 2.0 weight percent,

Oxide (MnO) have excellent piezoelectric properties for the properties are so much and so rigidly altered regardless of presence of manganous oxide (MnO) that the use in manufacturing ceramic wave lters and transduccoexistence of manganous oxide (MnO) hardly lmproves ers for mechanical llllem the propemes' Example 8.-Results shown in Table 8 In view of the above, a range between 0.02 Weight percent and 2.0 weight percent is selected for the effective Table 8 shows the piezoelectric properties of ceramics range of the nickel oxide (NiO) content. given by the formula Pb (ZrXTiySnZ)O3, where 0.47, 0.48,

It should be noted here that the improvements made and 0.05 are selected for x, y, and z, respectively, in one in the piezoelectric properties Iby addition of both nickel example (No. 24) and where 0.42, 0.48, and 0.10 are oxide (NiO) and manganous oxide (MnO) clearly reselected for x, y, and z, respectively, in another example sult from the presence of nickel and manganous ions. (No. 26) and of the ceramics obtained by adding, to each It is therefore possible, by introducing nickel ions 'into of these examples, 0.20 weight percent of nickel oxide the solution, to use, besides nickel oxide (NiO), nickel (NiO) and 0.20 weight percent of manganous oxide carbonate [NiCO32Ni(OH)24H2O] or any other nickel (MnO) (Nos. 25 and 27, respectively). compound which is easily thermally decomposed into 25 Comparison of the results of Nos. 4 and 6 of Table 5 nickel oxide (NiO). Likewise, manganous ions may be with the results of Table 8 makes it clear that substituput into the solution by using MnCO3, manganese dioxtion of Sn for a portion of Pb(Zr-Ti)03 does not ide (MnOz), or any other manganese compound which degrade piezoelectric properties which were improved by is easily converted at higher temperatures into MnO. In addition of both nickel oxide (NiO) and manganous case nickel compounds other than nickel oxide are utiloxide (MnO). In other words, substantially equal imized, they should be used in an amount equivalent to the provements in piezoelectric properties are expected by desired weight of nickel oxide (NiO). It is likewise true the addition of both nickel oxide (NiO) and manganous that manganese compounds other than manganous oxide oxlde (MnO) from the composition P1b(Zr-Ti-Sn)O3 as (MnO), if utilized, should be used in an amount equivafrom the composition Pb(Zr-Ti)O3.

TABLE s Kr Composition percent Qm Number Pb(Zro.41To.4sSIln.o5)0a 40 200 25- Pb(Zro.41Ti0.4gSn0 u5)Oa plus 0.20 wt. percent NiO plus 0.20 Wt. percent Mn0 63 910 26- Pb(Z1`o.4zTn.4sSno.1o) Oa 4l 300 27 Pb (Zro.4zTio.4aSn0.m) O3 plus 0.20 wt. percent NiO plus 0.20 Wt. percent MnO- 62 930 lent as calculated on the basis of the presence of manga- Example 9.-Resu1ts Shown in Table 9 nous oxide (MnO). Use of such compounds is exemplied by the compositions Nos. 7 and 9 of Table 5 and No. 45 In case at least one Amember of the group of calcium,

15 of Table 6. In this connection, it should be understood strontium and barium is substituted for 5 atom percent that nickel oxide (NiO) and manganous oxide (MnO) 0f Pb 1n the composition No. 27 shown in Table 8, then as used hereafter may also mean such nickel and manthe results shown in Table 9 are obtained.

TABLE 9 Composition percent Qm Nmll." (PbomsCaom) (Z1o.42Tio.4sSI1o.1u)0a plus 020 W percent NiO plus 0.20 Wt. percent MnO 59 910 30 (Pbmsrm) (Zra.4zTi,4gSno.m)0a plus 0.20 wt. percent NiO plus 0.20 Wt. percent MnO 63 920 31 (Pbu,5Ba005) (Zr0.42Tio.nSno.n) Oa plus 0.20 Wt. percent N iO plus 0.20 wt. percent Mn0 61 94o ganese compounds which may decompose at raised tem- Table 9 clearly demonstrates that piezoelectric propperatures into nickel oxide (NiO) and manganous oxide ertles are equally Well improved by the coexistence of (MDO) respectively, nickel oxide (NiO) and manganous oxide (MnO) for the cases where at least one member of the group of cal- Example' 7 "Resu1ts Shown m Table 7 cium, strontium and barium is substituted for a portion Table 7 shows typical piezoelectric Kr and Qm propof the basic composition (as in Table 9) and the cases erties of ceramics produced by selecting values of 0.00 where no such substitution is effected in such basic comfor z, 0.50-0.55 for x, and 0.50-O.45 for y, in the composition (as in No. 217, for example of Table 8). position P|b(ZrXTiySnz)O3 and by adding thereto both a 65 It should be noted again that the piezoelectric ceramic 0.20 weight percent of nickel oxide (NiO) and a 0.20 composition, improved as above indicated, can not be weight percent of manganous oxide (MnO). obtamed by presence of either one of the compounds TABLE 7 Kr, Composition percent Qm Number:

18- Pb(Zl'o.soTlu.tu)0a 29 340 19- Pb(Zr0.s0Ti,ngOa plus 0.20 wt. percent N10 plus 0.20 wt. percent Mn0 54 1, 060 20. Pb(Zro.5sTio.41 0a 41 300 21 Pb(Zr0 5aTi0,41)O4 plus 0.20 wt. percent N10 plus 0.20 wt. percent MnO. 65 920 22 Pb(ZI`o 55TO.45)0a 39 320 23 Pb(Zr0,55Ti,45)O3 plus 0.20 Wt. percent NlO plus 0.20 wt. percent MnO-... 56 1, 030

nickel oxide (NiO) or manganous oxide (MnO) alone; rboth compounds nickel oxide (NiO) and manganous oxide (MnO) should be present. It should further be noted that the piezoelectric properties referred to are obtained after polarization treatment carried out at temperatures (about 50 C.150 C.) higher than room temperature. lInasmuch as it is inevitable that polarizationtreatment practiced at room temperature reduces the value of the factor Kr, such low temperature polarization does not comply with the object of this invention.

FIGS. 5 and 6 show curves for the electromechanical coupling factor (Kr) and the mechanical quality factor Qm for basic compositions in which nickel oxide (NiO) and chromium sesquioxide (Cr203) are the additives.

Example 10.- Results shown in Table 10 The basic composition used in this example may be represented by the term Pb(Zr 52Ti0.48)O3, in which there are combined a powder consisting of 50 mol percent of lead monoxide (PbO), 26 mol percent of zirconium dioxide (ZrOz), and 24 mol percent of titanium dioxide (TiOz), with 0.50 rweight percent of nickel oxide (NiO) provided as an additional constituent, and with a further addition of chromium sesquioxide (Cr2O3) of from 0.01 weight percent to 0.50 weight percent. These were mixed in a ball mill, pre-sintered at 900 C. for an hour, crushed, press-moulded into discs, and sintered at 1300 C. for an hour. The resulting ceramic discs were provided with silver electrodes and piezoelectrically activated at 100 C. for an hour under an electric field of 50 kv./cm. After the discs have been allowed to stand for 24 hours, the electromechanical coupling factor Kr for the radial mode vibration and the mechanical quality factor Qm were measured to evaluate the piezoelectric activities. Typical results obtained are shown in the following Table 10.

lations obtained between factors Kr and Qm on the one hand and, on the other hand, the content of chromium sesquioxide (Cr203) in the case in which the composition Pb(Zr0-52Ti0 48)03 contains nickel oxide (NiO) of 0.50 weight percent and also chromium sesquioxide (Cr203) of 0.50 weight percent or less.

As will be clear from Table 10 and FIG. 5, it is possible to raise the factor Qm substantially and to increase the factor Kr by the addition of both nickel oxide (NiO) and chromium sesquioxide (Cr203) to the basic composition.

As already noted in other classes, an increase of one of the factors Kr and Qm reduces the other factor. But the addition of both compounds nickel oxide (NiO) and chromium sesquioxide (Cr203) to the basic composition simultaneously elevates factors Kr and Qm. This provides excellent compositions for use as the piezoelectric materials for ceramic wave filters where large Kr factors are required land in transducers for mechanical filters.

lf the content of chromium sesquioxide (CrzOa) is less than 0.01 weight percent, the coexistence of nickel oxide (NiO) and chromium sesquioxide (Cr203) serves little to improve the piezoelectric properties achieved by the presence of nickel` oxide (NiO) alone. If the content of chromium sesquioxide (Cr203) exceeds 0.5 Weight percent, the properties are so much altered regardless of presence of nickel oxide (NiO) that the coexistence of nickel oxide (NiO) scarcely improves the properties.

In view of the above, a range between 0.01 weight percent and 0.5 weight percent is selected for the effective range of the chromium sesquioxide (Cr203) content for the compositions considered.

Example 11.-Results shown by Table 11 Table l1 shows the results obtained for a mixture of the basic composition of Pb(Zr0 52Ti0.48)03 that is the TABLE Kr, Composition percent Qm Number:

1 Pb (ZrozTnJg) Oa 42 250 2.-.. Pb(Zr0.5zTi 4s)O3 plus 0.50 wt. percent NiO 56 260 3 Pb(Zr0,52TiU.4g)O3 plus 0.50 wt. percent NiO plus 0.01 wt. percent Cr203 60 290 4 Pb(Zro.52Ti0.4g)O3 plus 0.50 wt. percent NiO plus 0.02 wt. percent CrzOa. 64 380 5 Pb(Zro.szTio.4s)Oa plus 0.50 wt. percent NiO plus 0.05 wt. percent Cr203. 68 590 6.- Pb(Zro.s2Tia.4s)Oa plus 0.50 wt. percent NiO plus 0.10 wt. percent CrzOa 66 900 7. Pb(Zrn.52To.4g)O3 plus 0.50 wt. percent NiO plus 0.20 wt. percent CrzOs 1--.. 60 740 Pb(Zro.szTio.4s)O.-i plus 0.50 wt. percent NiO plus 0.30 wt. percent CrzOa 1-.... 58 620 Pb(Zro.s2Tu.4r)Oa plus 0.50 wt. percent NiO plus 0.50 wt. percent CrzOa. 56 350 1 Cr2(SO4)3 may be added as calculated on the basis of chromium sesquioxide (CrzOs).

Comparison of the results Nos. l and 2 of Table 10 shows that the addition of 0.50 weight percent of nickel oxide (NiO) alone to the basic composition provides piezoelectric material of raised Kr and Qm factors. However, the value of factor Qm attained by addition of nickel oxide (NiO) alone is still insuicient for many same as that employed in Example 10, but in` this case an additional constituent of 0.10 weight percent of chromium sesquioxide (Cr203) alone was used (No. 10) and there were other cases (Nos. 11 to 16) for mixtures with additions of nickel oxide (NiO) of from 0.02 weight percent to 2.0 weight percent.

TABLE 11 Composition percent Qm 10 Pb(Zru.5' Ti0.4sg0a plus 0.10 wt. percent CrzOa 53 780 11 Pb (Zr0,52Ti0.4g 03 plus 0.02 wt. percent NiO plus 0.10 wt. percent Cr203 53 780 12 Pb(Zrn.52Tu.4ggO3 plus 0.05 wt. percent NiO plus 0.10 wt. percent Cr203- 59 800 13 Pb(Zru.2Ti0.4s O3 plus 0.10 wt. percent NiO plus 0.10 wt. percent CrgOa. 64 830 14..-- Pb(Zru.s2Tio.4a)Oa plus 0.20 wt. percent N10 plus 0.10 wt. percent Cr203. 65 880 15 Pb(Zrn.52Ti0.4sg O3 plus 1.0 wt. percent NiO lplus 0.10 wt. percent Cr203 61 830 16 Pb(Zr0.52Tin 4s 03 plus 2.0 wt. percent NiO plus 0.10 wt. percent Cr2O3 55 790 1NiCo3-2Ni(O1El)g-4H2O was added as calculated on the basis of NiO.

purposes. A greater increase in the factor Qmy and a con- 7 current increase in the factor Kr would provide more improved piezoelectric materials having wider fields of application.

FIG. 5 illustrates curves representing the results of 0 Comparison of the result No. 1 of Example 10 with the result No. 10 in Table 11 shows that addition of 0.10 weight percent of chromium sesquioxide (Cr203) alone to the basic composition provides a piezoelectric material having fairly elevated Kr and Qm factors. It should be Example l0. More particularly, the curves show the reunderstood, however, that further increases in the factor 15 Kr and increases in factor Qm, which have already been increased by the addition of chromium sesquioxide (Cr203) alone, would provide piezoelectric materials having wider iields of application and hence these would constitute improved piezoelectric materials.

In FIG. 6, curves are shown representing the results of this Example 11. More particularly, these curves show the relation between factors Kr and Qm with respect to nickel oxide (NiO) when both nickel oxide (NiO) of 2.0 weight percent or less and chromium sesquioxide (Cr2O3) of 0.10 weight percent are added to the composition (ZI'0'52T0A8) O3.

As is clearly shown in Table 11 and FIG. 6, it is possible to provide excellent piezoelectric materials having substantially elevated Kr and Qm factors by the addition of both nickel oxide (NiO) and chromium sesquioxide (CMOS)- As in other cases, if the content of nickel oxide (NiO) is less than 0.02 weight percent, the coexistence of nickel (NiO) and chromium sesquioxide (Cr203), as used in accordance with this invention, may also mean or include such nickel and chromium compounds which may be decomposed at elevated temperatures into equivalent nickel oxide (NiO) and chromium sesquioxide (Cr2O3) compounds, respectively.

Example 12.-Results shown in Table 12 TABLE 12 Kr, Composition percent Qm Number:

17 Pb (Zro .soTio .50) Os 29 340 18... Pb(Zro.50Ti.5o)O3 plus 0.50 wt. percent N i0 plus 0.10 wt. percent Cr203 55 1, 020 19 Pb(ZI'0.53Tl0.41)O3 4l 300 20 Pb(Zra.saTi0.l1)O3 plus 0.50 wt. percent N10 plus 0.10 wt. percent Cr203 65 880 2l Pb(ZIn.55T0.45)O3 oxide (NiO) and chromium sesquioxide (Cr2O3) contributes little to the improvement of the piezoelectric properties attained by the addition of chromium sesquioxide (Cr203) alone. If the content of nickel oxide (NiO) exceeds 2.0 weight percent, the properties are considerably altered regardless of presence of chromium sesquioxide (Cr203). Hence, the coexistence of chromium sesquioxide (Cr203) hardly improves the properties.

In view of the above, a range between 0.02 Weight percent and 2.0 weight percent is selected for the effective range of the nickel oxide (NiO) content.

The improvements effected in the piezoelectric properties by addition of both nickel oxide (NiO) and chromium sesquioxide (Cr203) clearly result from presence of nickel and chromium ions. As in other cases, the ion content is the significant item. It is therefore possible, by introducing nickel ions into the mixture, to use, in substitution for nickel oxide (NiO), the compound nickel carbonate [NiCO3.2Ni(OH)2.4H2O] or any other nickel compound which is easily thermally decomposed into nickel oxide (NiO). Likewise, chromium ions may be put into the composition by using, instead of chromium sesquioxide (Cr2O3), the compound chromium sulphate [Cr2(SO4)3] or any other chromium compound which is easily thermally decomposed into chromium sesqui- Example 13.--Results shown in Table 13 Table 13 shows the piezoelectric properties of ceramics defined by the formla Pb(ZrXTiySnZ)O3, where 0.47, 0.48, and 0.05 are selected for x, y, and z, respectively, of certain compositions (No. 23 of Table 13), and where 0.42, 0.48, and 0.10 are selected for x, y, and z respec` tively, of certain other compositions (No. 25 of Table 13), and of the ceramics obtained by adding thereto 0.50 weight percent of nickel oxide (NiO) and 0.10 weight percent of chromium sesquioxide (Cr203) (Nos. 24 and 26 of Table 13).

oxide (Cr203). In case nickel and/or chromium compounds other than nickel oxide (NiO) and chromium sesquioxide (Cr203) are utilized, they should be used in amounts equivalent to their respective desired weights of nickel oxide (NiO) and chromium sesquioxide (Cr203). Use of such compounds is exemplified by the compositions Nos. 7 and 8 in Table 10 and No. 15 in Table 11. In

Comparison of the result No. 6 in Table 10 with the results in Table 13 makes it clear that substitution of tin (Sn) for a portion of Pb(Zr-Ti)03 does not substantially reduce the piezoelectric properties otherwise improved by addition of both nickel oxide (NiO) and chromium sesquioxide (CrzOg). In other Words, equal improvements in the piezoelectric properties are expected this connection, it should be understood that nickel oxide and obtained by addition of both nickel (NiO) and chromium sesquioxide (Cr203) from the generalized composition Pb(ZrTi-Sn)03 as from the generalized composition Pb(Zr-Ti)03.

Example 14.--Results shown in Table 14 understood that the general principles of this invention may be applied to other and widely varied compositions without departing from the spirit of the invention and the scope of the appended claims.

What is claimed is:

If at least 011e Ineflbel f the gfOUP COIISSDg 0f Cal- 5 1. A piezoelectric ceramic composition having a basic CIUITI (Ca), SrODilllm (ST), and bam-Url (Ba) 1S composition represented by the following compositional substituted for 5 atom percent of lead (Pb) in the comformula position No. 26 shown in Table 13, then the results shown in Table 14 are obtained. (PbuAv) (ZfxTlySnz) 03 TABLE 14 Kr. Composition percent Qm Number.

28. (Pbo.o5Cao,n 5) '(ZroAzTnAsSnmo) Oa plus 0.50 wt. percent N iO plus 0.10 Wt. percent CrzOg. 59 860 (ZroAzTiuAsSnoJo) Oa plus 0.50 wt. percent Ni 0 plus 0.10 wt. percent CMOL.-. (Pb0.5Bau5) (Zro.4zTio.4sSno.1o)Oa plus 0.50 wt. percent N10 plus 0.10 wt. percent CrzOL Table 14 clearly shows that the piezoelectric properties are equally well improved by the coexistence of nickel oxide (NiO) and chromium sesquioxide (Cr203) in the basic composition No. 26 of Table 13, where at least one member of the group of calcium (Ca), strontim (Sr), and barium (Ba) is substituted for a portion of the basic composition No. 26 and where no such substitution is eiiected.

It should lbe noted again that the piezoelectric ceramic composition improved as above can not be obtained by the addition of either nickel oxide (NiO) or chromium sesquioxide (Cr203) alone but only by the joint addition or coexistence of nickel oxide (NiO) and chromium sesquioxide (Cr203). It is repeated that the improvement in the piezoelectric properties is obtained through polarization treatment carried out at temperatures (about 50 C.-150 C.) higher than room temperature.

A considerable number of examples have 'been offered to establish the novelty and merit of a modified formula based on the formula expressed generally as (Pbu Av) (ZrxTiySnz) O3 Where A represents one or more of the elements calcium, strontium and barium and where The formulation, when modied as noted in the specication, produces outstanding piezoelectric ceramic materials. The modifications should include, according to this invention, any pair of the following three pairs of compounds:

Pair 1:

0.01-1.5 wt. percent Ga203 0.01-0.7 wt. percent Cr203 Pair 2:

0.02-0.1 wt. percent MnO 0.02-2.0 Wt. percent NiO Pair 3:

0.02-2.0 wt. percent NiO 0.01-0.5 wt. percent Cr203 While this invention has been set forth in certain particular compositions merely for illustration, it will be where A represents at least one member selected from a group consisting of calcium, strontium, and barium, and u, v, x, y, and z are given by characterized in that said ceramic composition contains a set of additional constituents consisting of a nickel compound equivalent in amount to nickel oxide of from 0.02 to 2.0 weight percent and a chromium compound equivalent in amount to a chromium sesquioxide of from 0.01 to 0.50 weight percent, each of said weight percentages being the percentage of the total weight of said ceramlc composition.

2. A piezoelectric ceramic composition according to claim 1, wherein the set of said additional constituents consistsof a nickel oxide of from 0.02 to 2.0 weight percent and a chromium sesquioxide of from 0.01 to 0.50 weight percent, each of the Weight percentages being the percentage of the total weight of said ceramic composition.

3. A piezoelectric ceramic composition having the folcharacterized in that said ceramic composition contains a set of additional constituents consisting of nickel oxide of from 0.02 to 2.0 weight percent and chromium sesquioxide of from 0.01 to 0.50 weight percent.

References Cited UNITED STATES PATENTS 2,928,163 3/ 1960 Berlincourt et al. 252-629` X 3,068,177 12/ 1962 Sugden 252-62.!)

TOBIAS E. LEVOW, Primary Examiner I. COOPER, Assistant Examiner U.S. Cl. XJR. 106-39 

